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Welding processes in shipbuilding industry

Welding processes in shipbuilding industry. C.G. Politis Deptartment of Naval Architecture Technological Educational Institute of Athens email : cpolitis@teiath.gr. General. General

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Welding processes in shipbuilding industry

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  1. Welding processes in shipbuilding industry C.G. Politis Deptartmentof Naval Architecture Technological Educational Institute of Athens email: cpolitis@teiath.gr Presentation name / Author: C.G. Politis

  2. General General Welding is the fusing of two metals by heating in order to produce a joint which is as strong as the parent metals. In principle all metals may be welded, but the degree of simplicity and the methods used vary considerably. In shipbuilding, welding process is now the accepted method of joining metals. All shipyard welding processes are of fusion type, where the edges of the joint are melted and fuse with the molten weld metal. The heat source of a fusion welding may be provided by gas torch, electric arc or electric resistance. Presentation name / Author

  3. Advantages over fasteners Presentation name / Author

  4. Residual Stresses and Distortion Residual stresses developed in a straight butt joint. Note that the residual stresses in (b) must be internally balanced. Distortion of a welded structure. Presentation name / Author

  5. Types of Welding Presentation name / Author

  6. Welding Standards List of Welding Standards http://www.wikiwand.com/en/List_of_welding_codes Presentation name / Author

  7. Joint types Welds are made at the junction of the various pieces that make up the weldment. The junctions of parts, or joints, are defined as the location where two or more members are to be joined. Parts being joined to produce the weldment may be in the form of rolled plate, sheet, pipes, castings or forgings. The five basic types of welding joints are listed below. Presentation name / Author

  8. Types of Welds (1) Presentation name / Author

  9. Types of Welds (2) Presentation name / Author

  10. Types of Welds (3) Groove Weld Fillet Weld Presentation name / Author

  11. Types of Welds (4) Presentation name / Author

  12. Types of Welds (5) Presentation name / Author

  13. Types of Welds (6) Presentation name / Author

  14. Types of Welds (7) Presentation name / Author

  15. Multi-pass weld This is the standard practice when welding a large joint. Because one bead of weld can’t do the job, the welder lays down a series of passes, using the order indicating in the Figure. Notice how the beads overlap. To prevent any gap in the weld the beads must be “wedded” together. In addition, a multipass weld has a tempering effect on the heat-affected zone. Presentation name / Author

  16. Basic Weld Symbols Presentation name / Author

  17. Weld joints Presentation name / Author

  18. Weld Symbols Presentation name / Author

  19. Welding Positions Presentation name / Author

  20. Methods of Welding Processes described include: Shielded Metal Arc Welding (SMAW) Gas Metal Arc Welding (GMAW or MIG– MAG) Gas Tungsten Arc Welding (GTAW or TIG) Submerged Arc Welding (SAW) Vertical Automatic Welding Processes (ESW, EGW Plasma Arc Welding (PAW) and cutting (PAC) . Presentation name / Author

  21. Shielded Metal Arc Welding (SMAW) GENERAL DESCRIPTION SHIELDED METAL ARC WELDING (SMAW) is an arc welding process in which coalescence of metals is produced by heat from an electric arc that is maintained between the tip of a covered electrode and the surface of the base metal in the joint being welded. The core of the covered electrode consists of either a solid metal rod or cast material or one fabricated by encasing metal powders in a metallic sheath. The core rod conducts the electric current to the arc and provides filler metal for the joint. The primary functions of the electrode covering are to provide arc stability and to shield the molten metal from the atmosphere with gases created as the coating decomposes from the heat of the arc. The shielding employed, along with other ingredients in the covering and the core wire, largely controls the mechanical properties, chemical composition, and metallurgical structure of the weld metal. The composition of the electrode covering varies according to the type of electrode. Presentation name / Author

  22. SMAW General View Presentation name / Author

  23. SMAW Principles of Operation Welding commences when an electric arc is struck between the tip of the electrode and the work. The intense heat of the arc melts the tip of the electrode and the surface of the work close to the arc. Tiny globules of molten metal rapidly form on the tip of the electrode, then transfer through the arc stream into the molten weld pool. In this manner, filler metal is deposited as the electrode is progressively consumed. The arc is moved over the work at an appropriate arc length and travel speed, melting and fusing a portion of the base metal and continuously adding filler metal. Since the arc is one of the hottest of the commercial sources of heat [temperatures above 9000 degrees F(5000 degrees C) have been measured at its centre], melting of the base metal takes place almost instantaneously upon arc initiation. If welds are made in either the flat or the horizontal position, metal transfer is induced by the force of gravity, gas expansion, electric and electromagnetic forces, and surface tension. For welds in other positions, gravity works against the other forces. Presentation name / Author

  24. SMAW Principles of Operation The sizes and types of electrodes for shielded metal arc welding define the arc voltage requirements (within the overall range of 16 to 40 V) and the amperage requirements (within the overall range of 20 to 550 A). The current may be either alternating or direct, depending upon the electrode being used, but the power source must be able to control the level of current within a reasonable range in order to respond to the complex variables of the welding process itself. During welding the current remains constant, even if the arc distance and voltage change. The SMAW machines have static dropping characteristic. The deposit rate is inferior to 1kg/h and the arc time is about 30%, due to the permanent need to change the consumable electrode. Presentation name / Author

  25. SMAW Principles of Operation DCSP (Direct Current Straight Polarity): Increases the weld penetration. DCRN(Direct Current Reverse Polarity): Causes heat to build up in the electrode, increasing the electrode melting rate and decreasing the depth of the weld. AC(Alternating Current): The resulting heat distribution provides a balance between the melting rate and penetration; Presentation name / Author

  26. SMAW Covered Electrodes In addition to establishing the arc and supplying filler metal for the weld deposit, the electrode introduces other materials into or around the arc, or both. Depending upon the type of electrode being used, the covering performs one or more of the following functions: Provides a gas to shield the arc and prevent excessive atmospheric contamination of the molten filler metal. Provides scavengers, deoxidizers, and fluxing agents to cleanse the weld and prevent excessive grain growth in the weld metal. Establishes the electrical characteristics of the electrode. Provides a slag blanket to protect the hot weld metal from the air and enhance the mechanical properties, bead shape, and surface cleanliness of the weld metal. Provides a means of adding alloying elements to change the mechanical properties of the weld metal. Presentation name / Author

  27. SMAW Covered Electrodes In addition to improving the mechanical properties of the weld metal, electrode coverings can be designed for welding with alternating current (AC). With AC, the welding arc goes out and is re-established each time the current reverses its direction. For good arc stability, it is necessary to have a gas in the arc stream that will remain ionized during each reversal of the current. This ionized gas makes possible the reignition of the arc. Gases that readily ionize are available from a variety of compounds, including those that contain potassium. It is the incorporation of these compounds in the electrode covering that enables the electrode to operate on AC. To increase the deposition rate, the coverings of some carbon and low alloy steel electrodes contain iron powder. The iron powder is another source of metal available for deposition, in addition to that obtained from the core of the electrode. The presence of iron powder in the covering also makes more efficient use of the arc energy. Metal powders other than iron are frequently used to alter the mechanical properties of the weld metal. Presentation name / Author

  28. SMAW ArcShielding THE ARC SHIELDING action is essentially the same for all electrodes, but the specific method of shielding and the volume of slag produced vary from type to type. The bulk of the covering materials on some electrodes is converted to gas by the heat of the arc, and only a small amount of slag is produced. Weld metal from such electrodes can be identified by the incomplete or light layer of slag which covers the bead. For electrodes at the other extreme, the bulk of the covering is converted to slag by the heat of the arc, and only a small volume of shielding gas is produced. The tiny globules of metal being transferred across the arc are entirely coated with a thin film of molten slag. This molten slag floats to the surface of the weld puddle because it is lighter than the metal. The slag solidifies after the weld metal has solidified. Welds made with these electrodes are identified by the heavy slag deposits that completely cover the weld beads. Between these extremes is a wide variety of electrode types, each with a different combination of gas and slag shielding. Presentation name / Author

  29. SMAW Arc Shielding Variations in the amount of slag and gas shielding also influence the welding characteristics of covered electrodes. Electrodes which produce a heavy slag can carry high amperage and provide high deposition rates, making them ideal for heavy weldments in the flat position. Electrodes which produce a light slag layer are used with lower amperage and provide lower deposition rates. These electrodes produce a smaller weld pool and are suitable for making welds in all positions. Because of the differences in their welding characteristics, one type of covered electrode usually will be best suited for a given application. Presentation name / Author

  30. SMAW Capabilities and Limitations SHIELDED METAL ARC WELDING is one of the most widely used processes, particularly for short welds in production, maintenance and repair work, and for field construction. Advantages: The equipment is relatively simple, inexpensive, and portable. The filler metal, and the means of protecting it and the weld metal from harmful oxidation during welding, are provided by the covered electrode. Auxiliary gas shielding or granular flux is not required. The process is less sensitive to wind than gas shielded arc welding processes. It can be used in areas of limited access. The process is suitable for most of the commonly used metals and alloys. Disadvantages Lower consumable efficiency (waste is produced) Difficult to use on thin materials High operator skill required Presentation name / Author

  31. SMAW Capabilities and Limitation SMAW electrodes are available to weld carbon and low alloy steels, stainless steels, cast irons, copper, and nickel and their alloys, and for some aluminium applications. Low melting metals, such as lead, tin, and zinc, and their alloys, are not welded with SMAW because the intense heat of the arc is too high for them. SMAW is not suitable for reactive metals such as titanium, zirconium, tantalum, and columbium because the shielding provided is inadequate to prevent oxygen contamination of the weld. Covered electrodes are produced in lengths of 9 to 18 in. (230 to 460 mm). The amount of current that can be used is limited by the electrical resistance of the core wire. Excessive amperage overheats the electrode and breaks down the covering. This, in turn, changes the arc characteristics and the shielding that is obtained. Because of this limitation, deposition rates are generally lower than for a welding process such as GMAW(Gas Metal Arc Welding). Presentation name / Author

  32. Gas Metal Arc Welding (GMAW) General Gas Metal Arc Welding (GMAW), also known as Metal Inert Gas (MIG) welding, is a welding process in which a low-voltage (18-40V) and high current (60-500A) electric arc is formed between a consumable wire electrode and the workpiece metals, heating them and causing them to melt and join. Along with the wire electrode, a shielding gas is fed through the welding gun, which shields the process from contaminated by the air. A constant voltage, direct current power source is most commonly used by GMAW. There are four primary methods of metal transfer in GMAW called: globular, dip or short-circuiting, spray and pulsed spray, each of which has advantages and limitations. Presentation name / Author

  33. GMAW – General view Presentation name / Author

  34. GMAW – Welding torches The typical GMAW gun has a number of key parts as: a control switch, a contact tip, a power cable, a gas nozzle, an electrode conduit and liner and a gas pipe. The control switch or trigger when pressed initiates the wire feed, the electric power and the shielding gas flow, causing an electric arc to be stuck. The gas nozzle is used to evenly direct the shielding gas into the welding zone; if the flow is not appropriate, it may not provide adequate protection of the weld area. Presentation name / Author

  35. GMAW – Modes of Metal Transfer Globular Transfer • It is characterized by a drop size with a diameter greater than the electrode itself. • The droplet detach when its weight exceeds the surface tension of the molten metal that holds the drop to the electrode tip. • It takes place with a positive electrode (DCRP) when the current is relatively low regardless of the type of shielding gas. • The molten drop grows in size from its lowest value with increasing current. Presentation name / Author

  36. GMAW – Modes of Metal Transfer Spray Transfer • Either pure Argon or Argon rich with 0.5% to 5% oxygen shielding gas is used. With such gas mixture a true spatter free, axial spray transfer becomes possible with higher current. • The minimum welding current at which spray transfer occurs is called the transition current. This depends on the metal wire diameter and shielding gas. Spray transfer mode can be used in any welding position, especially for welding plates, thick walled pipes and sections in the flat position. • The metal droplets being very small, short circuit does not occur and spatter is almost eliminated. • Using as shielding gas helium or a gas mixture with more than about 15% of CO2 there is no transition from globular to spray transfer. Also, there is no transition by using straight polarity. Presentation name / Author

  37. GMAW – Modes of Metal Transfer Pulsed Transfer Welding current switches automatically from a low level to a higher level in a periodic manner. Lower level current, also known as background current is set below the transition point and higher level is set well above the transition point in spray transfer range. Spray type metal transfer is achieved by applying pulses of higher level current, each pulse having a sufficient force to detach a droplet. The power supply is specially designed to produce a continuous wave form and pulses of the wave current. Presentation name / Author

  38. GMAW Pulsed Spray Transfer Presentation name / Author

  39. GMAW – Modes of Metal Transfer Short Circuit Transfer (Dip transfer) • It is used with low-current operation with lower electrode diameter. • The molten metal forming on the tip of the electrode wire is transferred by the wire dipping into the weld pool, thus causing a momentary short circuit. • In this way, metal is transferred only during the period when electrode tip is in contact with the weld pool. • This mode of transfer is preferred in vertical and overhead welding where the metal tends to run out of the joint under the action of gravity. Presentation name / Author

  40. GMAW – Welding Current Welding current depends upon welded metal thickness and metal transfer mode required, according to the parent metals properties. Presentation name / Author

  41. GMAW – Polarity • In GMAW we mainly use reverse polarity (DCRP). • DCRP eliminates arc blow • For welding sheet metal heating effect is produced mainly on electrode Presentation name / Author

  42. GMAW – Electrodes • In GMAW diameter of electrode normally ranges from 0.7 to 2.4 mm depending on welding current and metal thickness. • Electrode is made of the same metal as parent metal. In the case where an active shielding gas is used (mixture with O2 or CO2) electrode must be coated with deoxidizing agents such as copper. Presentation name / Author

  43. GMAW – Flux-cored wires Wires for GMAW welding are usually solid. For carbon, carbon manganese, high strength low alloy steels and stainless steels flux cored wires can be used. These offer the advantages of higher welding speeds and easier control of fillet weld profiles. Presentation name / Author

  44. GMAW – ShieldingGas According to the metal being welded we use: Pure Argon Argon mixed with small amounts of other gases Helium or Carbon dioxide Pure argon is particularly effective for welding aluminium and its alloys. Also used for copper and nickel. Mixtures of argon with carbon dioxide and other gases provide ideal arc conditions for spatter free welding of carbon, carbon-manganese and high strength low alloy steels in dip, spray and pulse transfer modes Presentation name / Author

  45. GMAW – Gas Flow Rate For different applications (modes of transfer) there are different flow rates: • For the spray and pulsed spray modes a flow rate of 10 l/min is suitable. • For globular mode a rate of 15 l/min is preferred. • For dip mode a good shielding environment is required so a flow rate between 20-25 l/min is used. Presentation name / Author

  46. GMAW – Advantages and Disadvantages Presentation name / Author

  47. Gas Tungsten Arc Welding (GTAW) General Gas Tungsten Arc Welding (GTAW), formerly known as Tungsten Inert Gas (TIG) Welding, is an electric-arc welding process that produces an arc between a non-consumable electrode and the work to be welded. The weld is shielded from the atmosphere by a shielding gas that forms an envelope around the weld area. Presentation name / Author

  48. GTAW General GTAW is versatile and can be used on ferrous and nonferrous metals and, depending on the base metal, in all welding positions. The process can be used to weld thin or thick materials with or without a filler metal. For thicker materials, an externally fed filler wire is generally used. The type of filler metal wire to be used is based on the chemical analysis of the base metal. The size of the filler metal wire depends on the thickness of the base metal, which usually dictates the welding current. Welding variables are selected after the base metal, filler metal, and joint configuration have been selected. The fixed welding variables include the type of filler metal, electrode type and size, the type of current, and the type of shielding gas. The primary adjustable variables for GTAW are welding current, arc length, and travel speed. Presentation name / Author

  49. GTAW Tungsten Electrodes The electrode material for GTAW is made from a tungsten alloy. Tungsten has one of the highest melting temperatures of any metal, about 6,170 degrees Fahrenheit (3,410 degrees Celsius). The size of an electrode to be used is determined by the welding current required. Larger electrodes permit higher currents to be used. Smaller diameter electrodes may be used for welding thinner materials. Presentation name / Author

  50. GTAW Shielding Gases Argon and helium are the two most commonly used shielding gases used for GTAW. Both gases are inert, causing an ionization effect in the welding arc. They protect the tungsten electrode and the molten weld pool from the atmosphere. Argon is heavier than helium and may be supplied in liquid or gaseous form. Argon is suitable for welding similar and dissimilar metals and works well while welding in the vertical and overhead welding positions. Helium is a lighter inert gas. It leaves the weld area faster than argon, and higher flow rates are necessary when using it. Helium produces a narrow but deep heat-affected zone (HAZ), which is good for welding on heavier metals. It is suitable for welding at high speeds and gives good coverage in vertical and overhead welding positions. It helps to increase the penetration. Helium is suitable for use on thicker nonferrous metals. Argon and helium mixtures can be also used. Argon and hydrogen mixtures are often used for welding of stainless steel. The typical mixture is a 95 per cent argon and 5 per cent hydrogen. Presentation name / Author

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